Phase segregation affects electron-phonon coupling in perovskite solar cell materials

Phase segregation has been described as a significant factor that limits solar cell efficiency and long-term stability in mixed organic-inorganic halide perovskite materials. It is often microscopically linked to the electron-phonon coupling when the device is under operation. Through computational calculations, Migdal-Eliashberg theory and the Frohlich large polaron model, we examined the control of phase segregation, in bulk I/Br and FA/Cs mixtures, over the electron-phonon coupling strength. We revealed that either A-site or X-site phase segregation destabilizes the material but reduces the electron-phonon coupling and increases the charge carrier mobility. Segregation promotes higher frequency vibrations and phonon instability is generally caused by [PbI6]4- octahedral torsions and liberations in FA+. Phonon dispersion has stronger control over the electron-phonon coupling than electronic bands. We expect that our theoretical findings will influence future discussions regarding the interplay of phase segregation and electron-phonon interactions in perovskite solar cells. Phase segregation has been described as a significant factor that limits solar cell efficiency and long-term stability in mixed organic-inorganic halide perovskite materials.